src/third_party/skia/include/private/SkTFitsIn.h - cobalt - Git at Google

 /*
  * Copyright 2013 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkTFitsIn_DEFINED
 #define SkTFitsIn_DEFINED

 #include "../private/SkTLogic.h"
 #include <limits>
 #include <type_traits>

 namespace sktfitsin {
 namespace Private {

 /** SkTMux::type = (a && b) ? Both : (a) ? A : (b) ? B : Neither; */
 template <bool a, bool b, typename Both, typename A, typename B, typename Neither>
 struct SkTMux {
     using type = skstd::conditional_t<a, skstd::conditional_t<b, Both, A>,
                                          skstd::conditional_t<b, B, Neither>>;
 };

 /** SkTHasMoreDigits = (digits(A) >= digits(B)) ? true_type : false_type. */
 template <typename A, typename B> struct SkTHasMoreDigits
     : skstd::bool_constant<std::numeric_limits<A>::digits >= std::numeric_limits<B>::digits>
 { };

 /** A high or low side predicate which is used when it is statically known
  *  that source values are in the range of the Destination.
  */
 template <typename S> struct SkTOutOfRange_False {
     using can_be_true = std::false_type;
     using source_type = S;
     static bool apply(S) {
         return false;
     }
 };

 /** A low side predicate which tests if the source value < Min(D).
  *  Assumes that Min(S) <= Min(D).
  */
 template <typename D, typename S> struct SkTOutOfRange_LT_MinD {
     using can_be_true = std::true_type;
     using source_type = S;
     static bool apply(S s) {
         using precondition = SkTHasMoreDigits<S, D>;
         static_assert(precondition::value, "minS > minD");

         return s < static_cast<S>((std::numeric_limits<D>::min)());
     }
 };

 /** A low side predicate which tests if the source value is less than 0. */
 template <typename D, typename S> struct SkTOutOfRange_LT_Zero {
     using can_be_true = std::true_type;
     using source_type = S;
     static bool apply(S s) {
         return s < static_cast<S>(0);
     }
 };

 /** A high side predicate which tests if the source value > Max(D).
  *  Assumes that Max(S) >= Max(D).
  */
 template <typename D, typename S> struct SkTOutOfRange_GT_MaxD {
     using can_be_true = std::true_type;
     using source_type = S;
     static bool apply(S s) {
         using precondition = SkTHasMoreDigits<S, D>;
         static_assert(precondition::value, "maxS < maxD");

         return s > static_cast<S>((std::numeric_limits<D>::max)());
     }
 };

 /** Composes two SkTOutOfRange predicates.
  *  First checks OutOfRange_Low then, if in range, OutOfRange_High.
  */
 template <typename OutOfRange_Low, typename OutOfRange_High> struct SkTOutOfRange_Either {
     using can_be_true = std::true_type;
     using source_type = typename OutOfRange_Low::source_type;
     static bool apply(source_type s) {
         bool outOfRange = OutOfRange_Low::apply(s);
         if (!outOfRange) {
             outOfRange = OutOfRange_High::apply(s);
         }
         return outOfRange;
     }
 };

 /** SkTCombineOutOfRange::type is an SkTOutOfRange_XXX type which is the
  *  optimal combination of OutOfRange_Low and OutOfRange_High.
  */
 template <typename OutOfRange_Low, typename OutOfRange_High> struct SkTCombineOutOfRange {
     using Both = SkTOutOfRange_Either<OutOfRange_Low, OutOfRange_High>;
     using Neither = SkTOutOfRange_False<typename OutOfRange_Low::source_type>;

     using apply_low = typename OutOfRange_Low::can_be_true;
     using apply_high = typename OutOfRange_High::can_be_true;

     using type = typename SkTMux<apply_low::value, apply_high::value,
                                  Both, OutOfRange_Low, OutOfRange_High, Neither>::type;
 };

 template <typename D, typename S, typename OutOfRange_Low, typename OutOfRange_High>
 struct SkTRangeChecker {
     /** This is the method which is called at runtime to do the range check. */
     static bool OutOfRange(S s) {
         using Combined = typename SkTCombineOutOfRange<OutOfRange_Low, OutOfRange_High>::type;
         return Combined::apply(s);
     }
 };

 /** SkTFitsIn_Unsigned2Unsiged::type is an SkTRangeChecker with an OutOfRange(S s) method
  *  the implementation of which is tailored for the source and destination types.
  *  Assumes that S and D are unsigned integer types.
  */
 template <typename D, typename S> struct SkTFitsIn_Unsigned2Unsiged {
     using OutOfRange_Low = SkTOutOfRange_False<S>;
     using OutOfRange_High = SkTOutOfRange_GT_MaxD<D, S>;

     using HighSideOnlyCheck = SkTRangeChecker<D, S, OutOfRange_Low, OutOfRange_High>;
     using NoCheck = SkTRangeChecker<D, S, SkTOutOfRange_False<S>, SkTOutOfRange_False<S>>;

     // If std::numeric_limits<D>::digits >= std::numeric_limits<S>::digits, nothing to check.
     // This also protects the precondition of SkTOutOfRange_GT_MaxD.
     using sourceFitsInDesitination = SkTHasMoreDigits<D, S>;
     using type = skstd::conditional_t<sourceFitsInDesitination::value, NoCheck, HighSideOnlyCheck>;
 };

 /** SkTFitsIn_Signed2Signed::type is an SkTRangeChecker with an OutOfRange(S s) method
  *  the implementation of which is tailored for the source and destination types.
  *  Assumes that S and D are signed integer types.
  */
 template <typename D, typename S> struct SkTFitsIn_Signed2Signed {
     using OutOfRange_Low = SkTOutOfRange_LT_MinD<D, S>;
     using OutOfRange_High = SkTOutOfRange_GT_MaxD<D, S>;

     using FullCheck = SkTRangeChecker<D, S, OutOfRange_Low, OutOfRange_High>;
     using NoCheck = SkTRangeChecker<D, S, SkTOutOfRange_False<S>, SkTOutOfRange_False<S>>;

     // If std::numeric_limits<D>::digits >= std::numeric_limits<S>::digits, nothing to check.
     // This also protects the precondition of SkTOutOfRange_LT_MinD and SkTOutOfRange_GT_MaxD.
     using sourceFitsInDesitination = SkTHasMoreDigits<D, S>;
     using type = skstd::conditional_t<sourceFitsInDesitination::value, NoCheck, FullCheck>;
 };

 /** SkTFitsIn_Signed2Unsigned::type is an SkTRangeChecker with an OutOfRange(S s) method
  *  the implementation of which is tailored for the source and destination types.
  *  Assumes that S is a signed integer type and D is an unsigned integer type.
  */
 template <typename D, typename S> struct SkTFitsIn_Signed2Unsigned {
     using OutOfRange_Low = SkTOutOfRange_LT_Zero<D, S>;
     using OutOfRange_High = SkTOutOfRange_GT_MaxD<D, S>;

     using FullCheck = SkTRangeChecker<D, S, OutOfRange_Low, OutOfRange_High>;
     using LowSideOnlyCheck = SkTRangeChecker<D, S, OutOfRange_Low, SkTOutOfRange_False<S>>;

     // If std::numeric_limits<D>::max() >= std::numeric_limits<S>::max(),
     // no need to check the high side. (Until C++11, assume more digits means greater max.)
     // This also protects the precondition of SkTOutOfRange_GT_MaxD.
     using sourceCannotExceedDest = SkTHasMoreDigits<D, S>;
     using type = skstd::conditional_t<sourceCannotExceedDest::value, LowSideOnlyCheck, FullCheck>;
 };

 /** SkTFitsIn_Unsigned2Signed::type is an SkTRangeChecker with an OutOfRange(S s) method
  *  the implementation of which is tailored for the source and destination types.
  *  Assumes that S is an usigned integer type and D is a signed integer type.
  */
 template <typename D, typename S> struct SkTFitsIn_Unsigned2Signed {
     using OutOfRange_Low = SkTOutOfRange_False<S>;
     using OutOfRange_High = SkTOutOfRange_GT_MaxD<D, S>;

     using HighSideOnlyCheck = SkTRangeChecker<D, S, OutOfRange_Low, OutOfRange_High>;
     using NoCheck = SkTRangeChecker<D, S, SkTOutOfRange_False<S>, SkTOutOfRange_False<S>>;

     // If std::numeric_limits<D>::max() >= std::numeric_limits<S>::max(), nothing to check.
     // (Until C++11, assume more digits means greater max.)
     // This also protects the precondition of SkTOutOfRange_GT_MaxD.
     using sourceCannotExceedDest = SkTHasMoreDigits<D, S>;
     using type = skstd::conditional_t<sourceCannotExceedDest::value, NoCheck, HighSideOnlyCheck>;
 };

 /** SkTFitsIn::type is an SkTRangeChecker with an OutOfRange(S s) method
  *  the implementation of which is tailored for the source and destination types.
  *  Assumes that S and D are integer types.
  */
 template <typename D, typename S> struct SkTFitsIn {
     // One of the following will be the 'selector' type.
     using S2S = SkTFitsIn_Signed2Signed<D, S>;
     using S2U = SkTFitsIn_Signed2Unsigned<D, S>;
     using U2S = SkTFitsIn_Unsigned2Signed<D, S>;
     using U2U = SkTFitsIn_Unsigned2Unsiged<D, S>;

     using S_is_signed = skstd::bool_constant<std::numeric_limits<S>::is_signed>;
     using D_is_signed = skstd::bool_constant<std::numeric_limits<D>::is_signed>;

     using selector = typename SkTMux<S_is_signed::value, D_is_signed::value,
                                      S2S, S2U, U2S, U2U>::type;
     // This type is an SkTRangeChecker.
     using type = typename selector::type;
 };

 template <typename T, bool = std::is_enum<T>::value> struct underlying_type {
     using type = skstd::underlying_type_t<T>;
 };
 template <typename T> struct underlying_type<T, false> {
     using type = T;
 };

 } // namespace Private
 } // namespace sktfitsin

 /** Returns true if the integer source value 's' will fit in the integer destination type 'D'. */
 template <typename D, typename S> inline bool SkTFitsIn(S s) {
     static_assert(std::is_integral<S>::value || std::is_enum<S>::value, "S must be integral.");
     static_assert(std::is_integral<D>::value || std::is_enum<D>::value, "D must be integral.");

     using RealS = typename sktfitsin::Private::underlying_type<S>::type;
     using RealD = typename sktfitsin::Private::underlying_type<D>::type;

     return !sktfitsin::Private::SkTFitsIn<RealD, RealS>::type::OutOfRange(s);
 }

 #endif
	/*
	* Copyright 2013 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkTFitsIn_DEFINED
	#define SkTFitsIn_DEFINED

	#include "../private/SkTLogic.h"
	#include <limits>
	#include <type_traits>

	namespace sktfitsin {
	namespace Private {

	/** SkTMux::type = (a && b) ? Both : (a) ? A : (b) ? B : Neither; */
	template <bool a, bool b, typename Both, typename A, typename B, typename Neither>
	struct SkTMux {
	using type = skstd::conditional_t<a, skstd::conditional_t<b, Both, A>,
	skstd::conditional_t<b, B, Neither>>;
	};

	/** SkTHasMoreDigits = (digits(A) >= digits(B)) ? true_type : false_type. */
	template <typename A, typename B> struct SkTHasMoreDigits
	: skstd::bool_constant<std::numeric_limits<A>::digits >= std::numeric_limits<B>::digits>
	{ };

	/** A high or low side predicate which is used when it is statically known
	* that source values are in the range of the Destination.
	*/
	template <typename S> struct SkTOutOfRange_False {
	using can_be_true = std::false_type;
	using source_type = S;
	static bool apply(S) {
	return false;
	}
	};

	/** A low side predicate which tests if the source value < Min(D).
	* Assumes that Min(S) <= Min(D).
	*/
	template <typename D, typename S> struct SkTOutOfRange_LT_MinD {
	using can_be_true = std::true_type;
	using source_type = S;
	static bool apply(S s) {
	using precondition = SkTHasMoreDigits<S, D>;
	static_assert(precondition::value, "minS > minD");

	return s < static_cast<S>((std::numeric_limits<D>::min)());
	}
	};

	/** A low side predicate which tests if the source value is less than 0. */
	template <typename D, typename S> struct SkTOutOfRange_LT_Zero {
	using can_be_true = std::true_type;
	using source_type = S;
	static bool apply(S s) {
	return s < static_cast<S>(0);
	}
	};

	/** A high side predicate which tests if the source value > Max(D).
	* Assumes that Max(S) >= Max(D).
	*/
	template <typename D, typename S> struct SkTOutOfRange_GT_MaxD {
	using can_be_true = std::true_type;
	using source_type = S;
	static bool apply(S s) {
	using precondition = SkTHasMoreDigits<S, D>;
	static_assert(precondition::value, "maxS < maxD");

	return s > static_cast<S>((std::numeric_limits<D>::max)());
	}
	};

	/** Composes two SkTOutOfRange predicates.
	* First checks OutOfRange_Low then, if in range, OutOfRange_High.
	*/
	template <typename OutOfRange_Low, typename OutOfRange_High> struct SkTOutOfRange_Either {
	using can_be_true = std::true_type;
	using source_type = typename OutOfRange_Low::source_type;
	static bool apply(source_type s) {
	bool outOfRange = OutOfRange_Low::apply(s);
	if (!outOfRange) {
	outOfRange = OutOfRange_High::apply(s);
	}
	return outOfRange;
	}
	};

	/** SkTCombineOutOfRange::type is an SkTOutOfRange_XXX type which is the
	* optimal combination of OutOfRange_Low and OutOfRange_High.
	*/
	template <typename OutOfRange_Low, typename OutOfRange_High> struct SkTCombineOutOfRange {
	using Both = SkTOutOfRange_Either<OutOfRange_Low, OutOfRange_High>;
	using Neither = SkTOutOfRange_False<typename OutOfRange_Low::source_type>;

	using apply_low = typename OutOfRange_Low::can_be_true;
	using apply_high = typename OutOfRange_High::can_be_true;

	using type = typename SkTMux<apply_low::value, apply_high::value,
	Both, OutOfRange_Low, OutOfRange_High, Neither>::type;
	};

	template <typename D, typename S, typename OutOfRange_Low, typename OutOfRange_High>
	struct SkTRangeChecker {
	/** This is the method which is called at runtime to do the range check. */
	static bool OutOfRange(S s) {
	using Combined = typename SkTCombineOutOfRange<OutOfRange_Low, OutOfRange_High>::type;
	return Combined::apply(s);
	}
	};

	/** SkTFitsIn_Unsigned2Unsiged::type is an SkTRangeChecker with an OutOfRange(S s) method
	* the implementation of which is tailored for the source and destination types.
	* Assumes that S and D are unsigned integer types.
	*/
	template <typename D, typename S> struct SkTFitsIn_Unsigned2Unsiged {
	using OutOfRange_Low = SkTOutOfRange_False<S>;
	using OutOfRange_High = SkTOutOfRange_GT_MaxD<D, S>;

	using HighSideOnlyCheck = SkTRangeChecker<D, S, OutOfRange_Low, OutOfRange_High>;
	using NoCheck = SkTRangeChecker<D, S, SkTOutOfRange_False<S>, SkTOutOfRange_False<S>>;

	// If std::numeric_limits<D>::digits >= std::numeric_limits<S>::digits, nothing to check.
	// This also protects the precondition of SkTOutOfRange_GT_MaxD.
	using sourceFitsInDesitination = SkTHasMoreDigits<D, S>;
	using type = skstd::conditional_t<sourceFitsInDesitination::value, NoCheck, HighSideOnlyCheck>;
	};

	/** SkTFitsIn_Signed2Signed::type is an SkTRangeChecker with an OutOfRange(S s) method
	* the implementation of which is tailored for the source and destination types.
	* Assumes that S and D are signed integer types.
	*/
	template <typename D, typename S> struct SkTFitsIn_Signed2Signed {
	using OutOfRange_Low = SkTOutOfRange_LT_MinD<D, S>;
	using OutOfRange_High = SkTOutOfRange_GT_MaxD<D, S>;

	using FullCheck = SkTRangeChecker<D, S, OutOfRange_Low, OutOfRange_High>;
	using NoCheck = SkTRangeChecker<D, S, SkTOutOfRange_False<S>, SkTOutOfRange_False<S>>;

	// If std::numeric_limits<D>::digits >= std::numeric_limits<S>::digits, nothing to check.
	// This also protects the precondition of SkTOutOfRange_LT_MinD and SkTOutOfRange_GT_MaxD.
	using sourceFitsInDesitination = SkTHasMoreDigits<D, S>;
	using type = skstd::conditional_t<sourceFitsInDesitination::value, NoCheck, FullCheck>;
	};

	/** SkTFitsIn_Signed2Unsigned::type is an SkTRangeChecker with an OutOfRange(S s) method
	* the implementation of which is tailored for the source and destination types.
	* Assumes that S is a signed integer type and D is an unsigned integer type.
	*/
	template <typename D, typename S> struct SkTFitsIn_Signed2Unsigned {
	using OutOfRange_Low = SkTOutOfRange_LT_Zero<D, S>;
	using OutOfRange_High = SkTOutOfRange_GT_MaxD<D, S>;

	using FullCheck = SkTRangeChecker<D, S, OutOfRange_Low, OutOfRange_High>;
	using LowSideOnlyCheck = SkTRangeChecker<D, S, OutOfRange_Low, SkTOutOfRange_False<S>>;

	// If std::numeric_limits<D>::max() >= std::numeric_limits<S>::max(),
	// no need to check the high side. (Until C++11, assume more digits means greater max.)
	// This also protects the precondition of SkTOutOfRange_GT_MaxD.
	using sourceCannotExceedDest = SkTHasMoreDigits<D, S>;
	using type = skstd::conditional_t<sourceCannotExceedDest::value, LowSideOnlyCheck, FullCheck>;
	};

	/** SkTFitsIn_Unsigned2Signed::type is an SkTRangeChecker with an OutOfRange(S s) method
	* the implementation of which is tailored for the source and destination types.
	* Assumes that S is an usigned integer type and D is a signed integer type.
	*/
	template <typename D, typename S> struct SkTFitsIn_Unsigned2Signed {
	using OutOfRange_Low = SkTOutOfRange_False<S>;
	using OutOfRange_High = SkTOutOfRange_GT_MaxD<D, S>;

	using HighSideOnlyCheck = SkTRangeChecker<D, S, OutOfRange_Low, OutOfRange_High>;
	using NoCheck = SkTRangeChecker<D, S, SkTOutOfRange_False<S>, SkTOutOfRange_False<S>>;

	// If std::numeric_limits<D>::max() >= std::numeric_limits<S>::max(), nothing to check.
	// (Until C++11, assume more digits means greater max.)
	// This also protects the precondition of SkTOutOfRange_GT_MaxD.
	using sourceCannotExceedDest = SkTHasMoreDigits<D, S>;
	using type = skstd::conditional_t<sourceCannotExceedDest::value, NoCheck, HighSideOnlyCheck>;
	};

	/** SkTFitsIn::type is an SkTRangeChecker with an OutOfRange(S s) method
	* the implementation of which is tailored for the source and destination types.
	* Assumes that S and D are integer types.
	*/
	template <typename D, typename S> struct SkTFitsIn {
	// One of the following will be the 'selector' type.
	using S2S = SkTFitsIn_Signed2Signed<D, S>;
	using S2U = SkTFitsIn_Signed2Unsigned<D, S>;
	using U2S = SkTFitsIn_Unsigned2Signed<D, S>;
	using U2U = SkTFitsIn_Unsigned2Unsiged<D, S>;

	using S_is_signed = skstd::bool_constant<std::numeric_limits<S>::is_signed>;
	using D_is_signed = skstd::bool_constant<std::numeric_limits<D>::is_signed>;

	using selector = typename SkTMux<S_is_signed::value, D_is_signed::value,
	S2S, S2U, U2S, U2U>::type;
	// This type is an SkTRangeChecker.
	using type = typename selector::type;
	};

	template <typename T, bool = std::is_enum<T>::value> struct underlying_type {
	using type = skstd::underlying_type_t<T>;
	};
	template <typename T> struct underlying_type<T, false> {
	using type = T;
	};

	} // namespace Private
	} // namespace sktfitsin

	/** Returns true if the integer source value 's' will fit in the integer destination type 'D'. */
	template <typename D, typename S> inline bool SkTFitsIn(S s) {
	static_assert(std::is_integral<S>::value \|\| std::is_enum<S>::value, "S must be integral.");
	static_assert(std::is_integral<D>::value \|\| std::is_enum<D>::value, "D must be integral.");

	using RealS = typename sktfitsin::Private::underlying_type<S>::type;
	using RealD = typename sktfitsin::Private::underlying_type<D>::type;

	return !sktfitsin::Private::SkTFitsIn<RealD, RealS>::type::OutOfRange(s);
	}

	#endif